PRELIMINARY RESULTS OF ESTIMATING SOIL MOISTURE OVER BARE SOIL USING FULL-POLARIMETRIC ALOS-2 DATA A. Sekertekin a, , A. M. Marangoz a , S. Abdikan a , M. T. Esetlili b a BEU, Engineering Faculty, Geomatics Engineering Department 67100 Zonguldak, Turkey - aliihsan_sekertekin, aycanmarangozhotmail.com, sabdikanbeun.edu.tr b EU, Faculty of Agriculture, Department of Soil Science and Plant Nutrition, Izmir, Turkey - tolga.esetliliege.edu.tr GeoAdvances 2016 KEY WORDS: Soil Moisture, Synthetic Aperture Radar SAR, ALOS-2, Backscattering coefficient σ o , Gravimetric Method ABSTRACT: Synthetic Aperture Radar SAR imaging system is one of the most effective way for Earth observation. The aim of this study is to present the preliminary results about estimating soil moisture using L-band Synthetic Aperture Radar SAR data. Full-polarimetric HH, HV, VV, VH ALOS-2 data, acquired on 22.04.2016 with the incidence angle of 30.4 o , were used in the study. Simultaneously with the SAR acquisition, in-situ soil moisture samples over bare agricultural lands were collected and evaluated using gravimetric method. Backscattering coefficients for all polarizations were obtained and linear regression analysis was carried out with in situ moisture measurements. The best correlation coefficient was observed with VV polarization. Cross-polarized backscattering coefficients were not so sensitive to soil moisture content. In the study, it was observed that soil moisture maps can be retrieved with the accuracy about 14 RMSE. Corresponding author

1. INTRODUCTION

Soil moisture is a key parameter for many environmental phenomena, especially for meteorological, agricultural and hydrological applications Verhoest et al., 2008; Ahmad et al., 2011; Lakshmi, 2013. In addition, soil moisture information can be used as an indicator for natural disasters such as flooding and droughts, and for environmental changes, such as dust storms and erosions Canada Center for Remote Sensing, 2008; Ahmad et al., 2011. Thus, monitoring spatial and temporal variations in soil moisture is of great importance for ecological balance. However, measuring accurate in situ soil moisture is expensive and time-consuming, also to observe temporal changes it requires repetitive measurements periodically. Remote sensing is an effective technology to understand the behaviour of the world and to evaluate the changes on Earth. Moreover, remote sensing is a potential alternative way for estimating the distribution and quantity of soil moisture at a variety of scales, without expensive, time-consuming and tiring in situ measurements Kornelsen Coulibaly, 2013. In recent years, radar remote sensing with different wavelengths is used to monitor spatial and temporal variations in soil moisture. Many studies have been presented to retrieve soil moisture content from X-band Aubert et al., 2011; Baghdadi et al., 2011; Zribi et al., 2012; Kseneman et al., 2012; Baghdadi et al., 2012; Kweon et al., 2012; Satalino et al., 2012 and C-band Gherboudj et al., 2011; Moran et al., 2011; Pasolli et al., 2011; Merzouki et al., 2011; Livens Verhoest, 2012; Jacome et al., 2013; Wang et al., 2013 SAR images; however, few studies were carried out using L-band Paloscia et al., 2012; Balenzano et al., 2013 SAR data. The only current operational high resolution L-band SAR satellite is ALOS-2 and the aim of this study is to investigate the effectiveness of new generation L-band satellite ALOS-2 images on estimating soil moisture content on bare soils.

2. STUDY AREA AND MATERIAL